Wind-resistant heating device using non-electric source

ABSTRACT

Disclosed is a wind-resistant heating device using a non-electric source. To this end, a non-electric heating body is received in the inner lower part of a main casing of a wind-resistant heating device. Air supply holes for supplying air for combustion are formed in the main casing. An upper opening for upward discharging heat generated when the non-electric heating body is combusted is formed in the main casing. Wind-resistant casings are spaced apart at a specific interval on the inside or outside of the main casing, thus preventing a head wind from flowing into the air supply holes of the main casing. Accordingly, although a head wind flows into the air supply holes of the main casing or the heating device is carried and moved, air can be changed into a flow of air to enable continuous combustion.

BACKGROUND OF THE INVENTION 1. Technical Field

The present invention relates to a wind-resistant heating device using a non-electric source and, more particularly, to a wind-resistant heating device using a non-electric source, wherein a non-electric heating body is received at the inner lower part of a main casing, air supply holes are formed to supply air, an upper opening is formed to discharge heat generated due to combustion, and a wind-resistant casing is spaced apart from the main casing at a specific interval inside or outside the main casing, thus preventing a head wind from entering the air supply holes.

2. Description of the Related Art

When temperature drops after the sunset or in the winter season, there are many difficulties in performing outdoor activities, such as fishing, camping, a stall, walk and cycling. Accordingly, measures for keeping warm are taken in performing outdoor activities. In most cases, outdoor activities are performed using an electric heating device or while a heating device using oil or coal is carried or used.

However, the electric heating device has a very limited environment in which it can be connected to a power source and also has a difficulty in generating heat when it rains or humidity is high although power can be supplied. Furthermore, the electric heating device has a danger of fire or electric shock attributable to moisture. In particular, if oil or coal is used, the electric heating device has limited transport and activities and has a danger of suffocation attributable to incomplete combustion or fire.

Furthermore, there is a case where a power source cannot be connected or oil or coal cannot be used due to the environmental restriction. In such a case, a heating device u sing a heat pack or solid fuel is commonly used.

In order to solve the above problems, the applicant of the present invention filed an application for Korean Patent Publication No. 10-2017-0100457 entitled “Height adjustable candle lifter and its seat” (Sep. 4, 2017) (hereinafter referred to as “Prior Art Document 1”).

Prior Art Document 1 uses a candle as a non-electric heating body, and is an invention proposed to uniformly secure heating efficiency by securing horizontality and maintaining a specific height although a candle is combusted and to prevent a user from being burnt although heat is rapidly delivered because a candle is placed in a seating unit.

In Prior Art Document 1, an air supply hole is formed to supply air for combustion so that a candle is stably combusted. If a strong a head wind blows or the heating device is placed in the moving seating unit, such as walk or cycling, there is a problem in that combusting candlelight goes out due to a wind introduced through the air supply holes.

Moreover, if the amount of supplied air is to be flexibly controlled, there is a limit to a selective application according to a use environment because there is no separate air control means for controlling the amount of supplied air.

Prior Art Document 1 has intended to solve the problem by additionally providing a housing, but has a difficulty in separating the housing from the seating unit because the housing is not integrated with the heating device and has many utilization restrictions.

Korean Patent No. 10-1583778 entitled “Warming up seat using candle” (Jan. 4, 2016) (hereinafter referred to as “Prior Art Document 2”) was proposed as another prior art document.

Prior Art Document 2 uses a candle as a heating body and can be conveniently used regardless of the place because it is coupled to a seat having convenient installation and transport. Prior Art Document 2 proposes a candlelight heating seating body having medical effects, such as relaxation of muscles, and capable of maintaining a body temperature outdoors by uniformly delivering heat using a heat storage distribution plate and a height control elastic body.

Prior Art Document 2 was designed to secure the amount of uniform heat although a candle is combusted because the wick of the candle is always provided at a constant position through the height control elastic body. However, there is a problem in that a candle loses its balance and is inclined or is fluctuated due to external vibration in a combustion process.

Furthermore, there is a problem in that a user suffers a burn due to the heating device heated up to a high temperature attributable to radiant heat generated as a candle is combusted. There is an additional limit because various non-electric heating bodies, such as gas and alcohol, cannot be used because a non-electric heating body included in the heating device is limited to a candle only.

SUMMARY OF THE INVENTION

The present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a wind-resistant heating device using a non-electric source, which can naturally change a flow of air to enable continuous combustion although a head wind blows or the heating device is carried and moved, can prevent a user's burn against radiant heat of a high temperature attributable to combustion, can flexibly control the amount of air depending on a season or temperature, can improve combustion efficiency by preventing the fluctuation of a non-electric heating body, and can use a variety of types of non-electric heating bodies.

In a wind-resistant heating device D using a non-electric heating body NB according to an embodiment of the present invention, the non-electric heating body NB is received in the inner lower part of a main casing 10 of the wind-resistant heating device D, air supply holes 11 for supplying air for combustion are formed in the main casing, an upper opening 12 for upward discharging heat generated when the non-electric heating body NB is combusted is formed in the main casing, and wind-resistant casings 20 and 30 are spaced apart at a specific interval on the inside or outside of the main casing 10, thus preventing a head wind from flowing into the air supply holes 11 of the main casing 10.

Furthermore, a lower casing 10 b may be coupled to the lower part of an upper casing 10 a of the main casing 10 in such a way as to be separated, and the lower part of the upper casing 10 a may be gradually expanded to form a slant part 13.

Furthermore, the lower casing 10 b of the main casing 10 may have a lower opening 14 a formed in a bottom plate 14, a support unit 15 may be positioned to be spaced apart from the bottom plate 14 at a specific interval, and the non-electric heating body NB may be positioned over the support unit 15.

Furthermore, a spring 16 may be positioned between the bottom plate 14 and the support unit 15 to pressurize the non-electric heating body NB upward.

Furthermore, a flow control part 17 to which a plurality of rotation wings 17 a is coupled in such a way as to be open or shut by the rotation of a rotation shaft 17 b may be provided in the lower opening 14 a of the bottom plate 14 to control the size of the lower opening 14 a.

Furthermore, the non-electric heating body NB may be received in the inner lower part of the inner wind-resistant casing 20, the lower part of an upper cylindrical part 22 in which an inflow hole 21 is formed may be gradually expanded to form a slant guide part 23, and a lower cylindrical part 24 may be positioned at the bottom of the slant guide part 23.

Furthermore, inflow holes 21 may be formed in the inner wind-resistant casing 20, and wind deflectors 21 a may be disposed to be inclined inside or outside in the inflow holes 21 to change the direction of a flow of air.

Furthermore, the wind deflector 21 a disposed in the inflow hole 21 may be disposed to be inclined outside, a blocking plate 21 b may be disposed at the outside end of the wind deflector 21 a, and the opening degree of the air supply hole 11 of the main casing 10 may be controlled by the blocking plate 21 b based on control of the relative position of the inner wind-resistant casing 20.

Furthermore, the main casing 10 and the inner wind-resistant casing 20 may be coupled up and down so that a relative position between the main casing 10 and the inner wind-resistant casing 20 may be adjusted. The slant part 13 of the main casing 10 and the slant guide part 23 of the inner wind-resistant casing 20 may be disposed to pass through a corresponding slant to adjust an interval between the slant part 13 and the slant guide part 23.

Furthermore, a plurality of fixing parts 18 spaced apart at specific intervals may be disposed alongside the inner circumference surface of the main casing 10 and coupled to the outer circumference surface of the inner wind-resistant casing 20. The fixing parts 18 may be coupled to the inner wind-resistant casing 20 so that the relative height of the fixing parts may be adjustable.

Furthermore, the fixing part 18 of the main casing 10 may include an elastic body, and the fixing part may be pressurized and coupled to the outer circumference surface of the inner wind-resistant casing 20 by applying an elastic force to the outer circumference surface.

Furthermore, the inner wind-resistant casing 20 may be spaced apart from the main casing 10 at a specific interval, and the inner wind-resistant casing 20 may be protruded upward so that combusted air is discharged to the outside through the upper opening 12.

Furthermore, a plurality of fixing elastic parts 25 may be radially disposed at the bottom of the inner wind-resistant casing 20 to pressurize and fix the non-electric heating body NB.

Furthermore, the fixing elastic parts 25 may have elastic jaws 25 a disposed therein and may be engaged with a bottom of the non-electric heating body NB or a trapping jaw G formed in the outer circumference surface of the non-electric heating body NB.

Furthermore, the outer wind-resistant casing 30 may be provided to surround the outside of the main casing 10, and a plurality of guidance holes 31 may be formed so that air may be supplied to the air supply holes 11.

Furthermore, the bottom of the outer wind-resistant casing 30 may be positioned to be seated in the slant part 13 of the main casing 10.

Furthermore, end guidance holes 31 a may be formed at the bottom of the outer wind-resistant casing 30, so air introduced into the end guidance holes 31 a is naturally changed into a flow of air by the slant part 13.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 to 4 are a perspective view, exploded perspective view, exploded sectional view and coupling sectional view of a wind-resistant heating device using a non-electric source according to an embodiment of the present invention.

FIGS. 5 to 7 are an exploded perspective view, exploded sectional view and coupling sectional view of a wind-resistant heating device using a non-electric source according to another embodiment of the present invention.

FIGS. 8 and 9 are a sectional perspective view and conceptual diagram of the flow control part of a bottom part according to an embodiment of the present invention.

FIG. 10 is a cross-sectional view of a wind-resistant heating device using a non-electric source according to an embodiment of the present invention.

FIGS. 11 and 12 are an exploded perspective view and coupling sectional view of a wind-resistant heating device using a non-electric source according to another embodiment of the present invention.

FIG. 13 is a sectional view of being the slant part and the slant guide part closely attached.

FIG. 14 is a sectional view of being the slant part and the slant guide part aparted.

DESCRIPTION OF REFERENCE NUMERALS

D: wind-resistant heating device NB: non-electric heating body 10: main casing 10a: upper casing 10b: lower casing 11: air supply hole 12: lower opening 13: slant part 14: bottom plate 14a: lower opening 15: support unit 16: spring 17: flow control part 17a: rotation wing 17b: rotation shaft 17c: wing jaw 17d: guidance hole 18: fixing part 18a: screw thread 18b: inclined surface 19: external interval rib G: trapping jaw 20: inner wind-resistant casing 20a: screw thread 21: inflow hole 21a: wind deflector 21b: blocking plate 22: upper cylindrical part 23: guide part 24: lower cylindrical part 25: fixing elastic part 25a: elastic jaw 30: outer wind-resistant casing 31: guidance hole 31a: end guidance hole 31b: assistant guidance hole 32: flange part 32a: rib groove C: coupling part

DETAILED DESCRIPTION

Embodiments of the present invention are described in detail with reference to the accompanying drawings.

FIG. 1 shows a wind-resistant heating device D using a non-electric source using a non-electric heating body NB according to an embodiment of the present invention. The wind-resistant heating device D includes a main casing 10, and an inner wind-resistant casing 20 and an outer wind-resistant casing 30 selectively provided on the inside and outside, respectively. The casings have a hollow type, and may be made of synthetic resin or metal material having a heat-resistant property.

The non-electric heating body NB described in the present invention is defined as a concept covering a heating body such as a lantern, torch or lighter using fuel, such as gas, alcohol or oil, in addition to a candle other than electricity.

Furthermore, the non-electric heating body NB may be fabricated to include a container part that may be filled. For example, the container part may be filled with a candle having a wick.

The present invention does not have an object of heating a specific object simply, but has an object of keeping warm the body, such as a user or pet dog, for cold protection in the open air or an area having a low temperature in a portable type. In general, a frame applied to the non-electric heating body NB may have a diameter of 20 mm or less and height of 50 mm or less. The subject of the flame is natural combustion using the air in the atmosphere without an additional combustion target.

As shown in FIGS. 2 and 3, the non-electric heating body NB is received at the inner lower part of the main casing 10 of the wind-resistant heating device D. Air supply holes 11 are formed in the main casing 10 to supply air for combustion. An upper opening 12 for upward discharging heat generated when the non-electric heating body NB is combusted is formed in the main casing 10.

The air supply holes 11 continue to supply air so that continuous combustion is performed.

The inner wind-resistant casing 20 or the outer wind-resistant casing 30 provided on the inside or outside of the main casing 10 is spaced apart from the main casing 10 at a specific interval, thus preventing a head wind from entering the air supply holes 11 of the main casing 10 and also naturally enabling the circulation of air through the space between the inner wind-resistant casing 20 and the outer wind-resistant casing 30.

Accordingly, the main casing 10 can be cooled even in radiant heat of a high temperature attributable to combustion. A burn that may occur when a user carries the main casing 10 can be prevented.

Furthermore, as shown in FIG. 10, wind deflectors 11 a are disposed to be inclined inside or outside in the air supply holes 11 of the main casing 10, thus being capable of changing a flow direction of air.

The wind deflector 11 a may have one side coupled to the air supply hole 11 and the other side inclined inward. The wind deflector may be disposed to be bent inward by perforating the air supply hole 11 in its fabrication process.

The wind deflectors 11 a can form a convection current of air within the upper casing 20 by changing a flow of air in parallel to the forming direction of the wind deflectors 11 a, thereby preventing the extinguishment of a flame attributable to a head wind and controlling temperature of the upper casing 20 that has risen to a high temperature.

In the main casing 10, a lower casing 10 b may be coupled to an upper casing 10 a in such a way as to be separated. The upper casing 10 a and the lower casing 10 b may have screw threads formed in their upper and lower parts, respectively, and screwed together. In addition, they may be fabricated to be coupled by various known coupling means, such as fit coupling using engagement means.

Furthermore, as shown in FIG. 3, the lower part of the upper casing 10 a may be gradually expanded to form a slant part 13. The top of the non-electric heating body NB provided in a bottom plate 14 is closely attached to the slant part 13 so that the non-electric heating body NB can be stably received regardless of the diameter or type of the non-electric heating body NB.

As shown in FIGS. 5 and 6, in the lower casing 10 b of the main casing 10, a lower opening 14 a is formed in the bottom plate 14. A support unit 15 is positioned to be spaced apart from the bottom plate 14 at a specific interval. The non-electric heating body NB may be provided at the top of the support unit 15.

The lower opening 14 a formed in the bottom plate 14 of the lower casing 10 b enables air to be introduced from the bottom, thus forming a circulation flow of the air that leads to the upper opening 12.

The lower casing 10 b may have an internal diameter slightly greater than the diameter of the non-electric heating body NB. Accordingly, a space is formed between the lower casing 10 b and the non-electric heating body NB, so the air can circulate to the space.

In this case, since the support unit 15 is spaced apart from the bottom plate 14 of the main casing 10 at a specific interval, the air can be stably supplied without blocking the lower opening 14 a although the non-electric heating body NB is provided.

Furthermore, a spring 16 may be provided between the bottom plate 14 and the support unit 15 to pressurize the non-electric heating body NB upward.

If the non-electric heating body NB is provided in the lower casing 10 b of the main casing 10, the spring 16 provided at the inner bottom of the non-electric heating body NB can apply an upward elastic force so that the spring 16 is closely attached to the slant part 13 regardless of the height of the non-electric heating body NB.

The spring 16 may be configured using various members, such as an elastic wire using rubber, in addition to a coil spring or a sheet spring. In particular, in the case of a candle, the spring may apply a continuous elastic force regardless of the length of the candle so that a flame generated at the top of the candle is placed at a specific location.

In this case, as shown in FIG. 7, the support unit 15 may be provided at the top of the spring 16 to stably support the bottom of the candle. A magnetic body M may be provided in the support unit 15 to generate an adhesive power between the spring 16 and a metal piece or a container part made of metal at the bottom of the wick of the candle provided at the container part of the non-electric heating body NB.

As shown in FIG. 8, the plurality of rotation wings 17 a of a flow control part 17 is coupled to the lower opening 14 a of the bottom plate 14 in such a way as to be open or shut by the rotation of a rotation shaft 17 b. Accordingly, the size of the lower opening 14 a can be adjusted.

The open and shut degree of the rotation wing 17 a is changed by the rotation of the rotation shaft 17 b, so the size of the lower opening 14 a can be flexibly adjusted. A wing jaw 17 c may be positioned in the outer circumference part of each of the rotation wings 17 a.

As shown in FIG. 8, the rotation wing 17 a is fabricated to adjust its angle with respect to its position in addition to its open and shut degree, thereby being capable of controlling the direction of a flow of air and a fine flow. For example, as shown in FIG. 9, when the wing jaw 17 c is located to correspond to the direction of a head wind, the inflow of air can be blocked. In contrast, when the wing jaw 17 c is located on the side opposite the head wind of the wing jaw 17 c, air can naturally flow into an induction hole 17 d formed in the rotation wing 17 a.

In this case, the induction hole 17 d may be circular, but may be a long hole.

As shown in FIG. 11, the inner wind-resistant casing 20 may receive the non-electric heating body NB in its inner lower part in such a way as to surround the non-electric heating body NB. The inner wind-resistant casing 20 includes a plurality of inflow holes 21 so that the air can continue to be supplied.

The inner wind-resistant casing 20 can prevent the upper casing 20 from rising to a high temperature by blocking radiant heat attributable to the combustion of the non-electric heating body NB, can remove a danger of a burn that may occur due to a user's carelessness, and thus can prevent a fire.

In this case, the inflow hole 21 may have various shapes, such as a horizontal type, a vertical type and a diagonal type. Although not shown, if the inflow hole 21 has a diagonal type, flows of air circulations in the horizontal and vertical directions can be generated at the same time.

As shown in FIG. 11, in the inner wind-resistant casing 20, the bottom of an upper cylindrical part 22 may be gradually expanded to form a slant guide part 23. A lower cylindrical part 24 may be positioned at the bottom of the slant guide part 23.

The inflow holes 21 may be formed in the upper cylindrical part 22. The slant guide part 23 may be positioned to have both an inner circumference surface and an outer circumference surface pass through an inclined surface. A flow of air supplied from the air supply holes 11 of the main casing 10 or the lower opening 14 a can be naturally changed by the slant guide part 23.

Furthermore, if the non-electric heating body NB is provided, the top pyramidal surface of the slant guide part 23 functions to continuously come into contact with the non-electric heating body NB regardless of the size of the diameter of the slant guide part 23. Accordingly, the non-electric heating body NB having various standards, such as a gas canister, is closely attached to the slant guide part 23 and can be prevented from being detached therefrom. In particular, a candle can be guided to maintain balance by applied pressure of the spring 16 although the candle has its top molten and becomes a semi-liquid state. Since the top pyramidal surface of the candle closely comes into contact with the slant guide part 23, a problem in that a surrounding environment becomes dirty in addition to the main casing 10 can be prevented because wax drippings can be prevented from flowing.

Wind deflectors 21 a are also disposed to be inclined inside or outside in the inflow holes 21 of the inner wind-resistant casing 20, thereby being capable of changing the direction of a flow of air.

Furthermore, the wind deflector 21 a positioned in the inflow hole 21 may be positioned to be inclined to the outside, and a blocking plate 21 b may be positioned at the outside end of the wind deflectors 21 a. In this case, the open and shut degree of air supply hole 11 of the main casing 10 can be adjusted by the blocking plate 21 b through the adjustment of a relative position of the inner wind-resistant casing 20.

A method of adjusting the relative position of the inner wind-resistant casing 20 may include an up and down movement, such as that shown in FIGS. 13 and 14, and a rotation movement (not shown). The wind deflectors 21 a and the blocking plates 21 b integrated with the inner wind-resistant casing 20 may move up and down and rotate, thus shutting or opening the air supply holes 11 formed in the main casing 10.

Accordingly, fire power and/or a temperature can controlled depending on a use environment because the amount of air supplied can be controlled depending on the degree that the blocking plates 21 b blocks the air supply holes 11.

The main casing 10 and the inner wind-resistant casing 20 may be coupled so that a relative position between them is adjusted up and down. The slant part 13 of the main casing 10 and the slant guide part 23 of the inner wind-resistant casing 20 may be disposed to pass through a corresponding slant.

Accordingly, the interval between the slant part 13 and the slant guide part 23 is different depending on a relative up and down location. When the slant part 13 and the slant guide part 23 closely adhere, the supply of air is blocked. When the slant part 13 and the slant guide part 23 maintains an interval, air is supplied. Accordingly, fire power and/or a temperature can be controlled depending on a use environment by controlling the interval.

Specifically, if the wind-resistant heating device D is fixed and used, a danger that a flame will extinguish is low although air is supplied to the air supply holes 11 formed in the main casing 10 as shown in FIG. 13. Accordingly, a flow of air can be blocked by bringing the slant part 13 and the slant guide part 23 to closely adhere. At this time, the blocking plates 21 b may be manipulated to open the air supply holes 11.

In contrast, if the wind-resistant heating device D is used while moving, a flame may extinguish because a head wind flows into the air supply holes 11 of the main casing 10 as shown in FIG. 14. Accordingly, the interval between the slant part 13 and the slant guide part 23 may be widened to induce a flow of air. At this time, the blocking plates 21 b may be manipulated to block the air supply holes 11.

In contrast, if the main casing 10 or the inner wind-resistant casing 20 needs to be cooled, a flow of air by opening the air supply holes 11 from the blocking plates 21 b and simultaneously widening the interval between the slant part 13 and the slant guide part 23.

In this case, a plurality of fixing parts 18 spaced at specific intervals is disposed alongside the inner circumference surface of the main casing 10, and is coupled to the outer circumference surface of the inner wind-resistant casing 20. In this case, the fixing parts 18 may be coupled to the inner wind-resistant casing 20 in such a way as to control their relative height.

In one embodiment, as shown in FIGS. 4 and 7, a screw thread 18 a may be formed in the fixing part 18 of the main casing 10 and a screw thread 20 a may be formed in the outer circumference surface of the inner wind-resistant casing 20. Accordingly, the fixing part 18 and the inner wind-resistant casing 20 are screwed to enable control of a relative height.

In another embodiment, as shown in FIG. 12, the fixing part 18 may have an elastic body and may be pressurized and coupled to the outer circumference surface of the inner wind-resistant casing 20 by an elastic force. In this case, the fixing part 18 may be fabricated using a synthetic resin piece or may be positioned to be elastically deformed by bending a metal piece. An inclined surface 18 b may be formed on one side of the fixing part 18, thereby facilitating an up and down movement despite pressurization by an elastic force.

The fixing part 18 functions to couple the main casing 10 and the inner wind-resistant casing 20, but the main casing 10 and the inner wind-resistant casing 20 may be spaced apart at a specific interval through the medium of the fixing part 18. The fixing part 18 also functions to provide the inner wind-resistant casing 20 at the accurate position of the main casing 10.

Coupling parts C coupled to a heated seating body are disposed at the upper part of a casing that belongs to the main casing 10 and the inner wind-resistant casing 20 and that is relatively protruded upward.

In this case, the coupling parts C may be formed in various forms and may be fabricated to secure an adhesive power by coupling a magnetic body.

Furthermore, as shown in FIG. 12, the inner wind-resistant casing 20 is spaced apart from the main casing 10 at a specific interval. In this case, the inner wind-resistant casing 20 is protruded upward so that combusted air is discharged to the outside through the upper opening 12. Accordingly, a continuous upper and lower flow of air can be induced, and the seating body can maintain a constant temperature without rising to an excessive temperature.

As shown in FIGS. 4 and 12, a plurality of fixing elastic parts 25 may be disposed in a radial form at the lower part of the inner wind-resistant casing 20, thus being capable of pressurizing and fixing the non-electric heating body NB.

The fixing elastic part 25 may be made of a metal material or synthetic resin material and may be integrated with the inner wind-resistant casing 20 using the same material. In this case, the plurality of fixing elastic parts 25 may be deployed in a radial form so that they apply equal applied pressure.

In this case, as shown in FIG. 4, the fixing elastic part 25 has a bending part 25 b so that it has an inward bent shape. Accordingly, the non-electric heating body NB or the outer circumference surface of the container part thereof can be pressurized and fixed to the bending parts 25 b.

As shown in FIG. 12, the fixing elastic part 25 has an elastic jaw 25 a on the inside thereof, so the elastic jaws may be engaged with the bottom of the non-electric heating body NB or a trapping jaw G formed in the outer circumference surface of the non-electric heating body NB.

The elastic jaws 25 a may simply pressurize the side of the non-electric heating body NB or the container part, but may be fabricated to be engaged with the bottom thereof. In another embodiment, if the trapping jaw G is formed in the outer circumference surface of the non-electric heating body NB or the container part, there is an advantage in that stable fixing is possible despite an external force that may occur during use because the trapping jaw G can be engaged with the elastic jaw 25 a.

Furthermore, the non-electric heating body NB or the container part can be separated from the fixing elastic parts 25 by slightly applying an external force. Accordingly, the non-electric heating body NB or the container part can be easily separated from the fixing elastic parts after the wind-resistant heating device is used, and can be easily coupled when they are coupled.

The outer wind-resistant casing 30 is provided to surround the outside of the main casing 10, and may include a plurality of guidance holes 31 so that air is supplied to the air supply holes 11.

The outer wind-resistant casing 30 functions to prevent a flame from extinguishing by blocking a head wind and also to cool the main casing 10 having a temperature raised to a high temperature.

In this case, the guidance holes 31 may be formed to go across the air supply holes 11 formed in the outer wind-resistant casing 30 so that a head wind is not guided. If the upper casing 10 a and lower casing 10 b of the main casing 10 are screwed by the screw threads, a relative position between the air supply holes 11 and guidance holes 31 may be controlled by controlling the degree that the upper casing 10 a and lower casing 10 b are coupled. Accordingly, the degree that a head wind flows in can be controlled.

The bottom of the outer wind-resistant casing 30 may be provided to be seated in the slant part 13 of the main casing 10.

Furthermore, end guidance holes 31 a may be formed at the bottom of the outer wind-resistant casing 30 so that air guided into the end guidance holes 31 a is naturally changed to a flow of air by the slant part 13.

That is, a flow of air is guided into the end guidance holes 31 a provided on the slant part 13, and the air may be naturally changed in the vertical direction alongside the slant part 13.

If outdoor air temperature is relatively low and thus a user feels the cold, the main casing 10 may be controlled to rise to a high temperature because the end guidance holes 31 a formed in the outer wind-resistant casing 30 are directed toward the upper side.

Accordingly, the user can flexibly control temperature because the end guidance holes 31 a formed in the outer wind-resistant casing 30 are differently located on the upper or lower side depending on outside air temperature.

Furthermore, multiple assistant guidance holes 31 b are formed on the side of the outer wind-resistant casing 30, thus being capable of preventing the extinguishment of a flame that may occur when a flow of air is blocked.

A plurality of external interval ribs 19 is disposed in the outer circumference surface of the main casing 10. Accordingly, the outer wind-resistant casing 30 is located at the center without being slanted in a specific direction, and a specific interval is formed between the main casing 10 and the outer wind-resistant casing 30, thereby making uniform a flow of air.

In this case, a flange part 32 is positioned at the top of the outer wind-resistant casing 30, and a plurality of rib grooves 32 a may be disposed in the flange part so that the external interval ribs 19 are inserted into the rib grooves 32 a, respectively. Accordingly, the outer wind-resistant casing 30 can be precisely seated in a specific position because the rib grooves 32 a are disposed at the locations of the external interval ribs 19.

Furthermore, although not shown, if the external interval ribs 19 are disposed to be inserted into the rib grooves 32 a, the outer wind-resistant casing 30 can be prevented from being turned or detached due to an external force.

The wind-resistant heating device using a non-electric source according to the embodiment of the present invention can change a flow of air to enable continuous combustion although a head wind flows into the air supply holes of the upper casing or the heating device is carried and moved because the wind-resistant casing is provided on the inside or outside of the main casing.

Furthermore, a user's burn can be prevented with respect to radiant heat of a high temperature attributable to combustion because the inner wind-resistant casing is provided in the upper casing.

Moreover, air can be stably supplied although the non-electric heating body is provided because the support unit is spaced apart from the bottom plate of the main casing at a specific interval.

Furthermore, the main casing includes the slant part and the bottom plate includes the spring, thereby upward pressurizing the non-electric heating body. Accordingly, there is an advantage in that the utilization of the wind-resistant heating device is high because non-electric heating bodies having various sizes and types can be stably received.

Furthermore, the amount of air can be flexibly controlled by adjusting the size of the lower opening because the flow control part to which the plurality of rotation wings is coupled to be open or shut is provided in the lower opening of the bottom plate.

Furthermore, the main casing and the inner wind-resistant casing are coupled up and down so that a relative position thereof is controlled, thereby being capable of controlling temperature.

In addition, the amount of air can be controlled by adjusting the interval between the slant part of the main casing and the slant guide part of the inner wind-resistant casing.

Furthermore, the direction of supplied air can be naturally changed because the wind deflectors are provided in the air supply holes of the main casing or the inflow hole of the inner wind-resistant casing.

Furthermore, the plurality of fixing elastic parts is disposed at the bottom of the inner wind-resistant casing in a radial form. Accordingly, there are advantages in that a fixation power can be secured because the non-electric heating body can be pressurized and fixed and maintenance is easy because the non-electric heating body can be easily attached or detached.

A flow of air flowing into the outer wind-resistant casing can be naturally changed by the slant part because the slant part is positioned in the main casing. Accordingly, the upper casing raised to a high temperature due to radiant heat of combustion can be cooled by the flow of air.

Furthermore, the end guidance holes are formed at the bottom of the outer wind-resistant casing to guide a flow of air, but the locations of the end guidance holes are changed to the upper or lower side depending on a season or temperature.

Accordingly, temperature can be flexibly controlled by changing the direction in which a wind is introduced.

The wind-resistant heating device D using a non-electric source according to the present invention is not limited to the embodiments, and the range that those skilled in the art to which the present invention pertains may change the present invention in various ways without departing from the gist of the present invention claimed in the claims should be construed as belonging to the scope of protection of the claims. 

What is claimed is:
 1. A wind-resistant heating device D using a non-electric heating body NB, wherein the non-electric heating body NB is received in an inner lower part of a main casing 10 of the wind-resistant heating device D, air supply holes 11 for supplying air for combustion are formed in the main casing, an upper opening 12 for upward discharging heat generated when the non-electric heating body NB is combusted is formed in the main casing, and wind-resistant casings 20 and 30 are spaced apart at a specific interval on an inside or outside of the main casing 10, thus preventing a head wind from flowing into the air supply holes 11 of the main casing
 10. 2. The wind-resistant heating device of claim 1, wherein: a lower casing 10 b is coupled to a lower part of an upper casing 10 a of the main casing 10 in such a way as to be separated, and the lower part of the upper casing 10 a is gradually expanded to form a slant part
 13. 3. The wind-resistant heating device of claim 2, wherein: the lower casing 10 b of the main casing 10 has a lower opening 14 a formed in a bottom plate 14, a support unit 15 is positioned to be spaced apart from the bottom plate 14 at a specific interval, and the non-electric heating body NB is positioned over the support unit
 15. 4. The wind-resistant heating device of claim 3, wherein a spring 16 is positioned between the bottom plate 14 and the support unit 15 to pressurize the non-electric heating body NB upward.
 5. The wind-resistant heating device of claim 3, wherein a flow control part 17 to which a plurality of rotation wings 17 a is coupled in such a way as to be open or shut by a rotation of a rotation shaft 17 b is provided in the lower opening 14 a of the bottom plate 14 to control a size of the lower opening 14 a.
 6. The wind-resistant heating device of claim 1, wherein: the non-electric heating body NB is received in the inner lower part of the inner wind-resistant casing 20, a lower part of an upper cylindrical part 22 in which an inflow hole 21 is formed is gradually expanded to form a slant guide part 23, and a lower cylindrical part 24 is positioned at a bottom of the slant guide part
 23. 7. The wind-resistant heating device of claim 1, wherein: inflow holes 21 are formed in the inner wind-resistant casing 20, and wind deflectors 21 a are disposed to be inclined inside or outside in the inflow holes 21 to change a direction of a flow of air.
 8. The wind-resistant heating device of claim 7, wherein: the wind deflector 21 a disposed in the inflow hole 21 is disposed to be inclined outside, a blocking plate 21 b is disposed at an outside end of the wind deflector 21 a, and an opening degree of the air supply hole 11 of the main casing 10 is controlled by the blocking plate 21 b based on control of a relative position of the inner wind-resistant casing
 20. 9. The wind-resistant heating device of claim 6, wherein: the main casing 10 and the inner wind-resistant casing 20 are coupled up and down so that a relative position between the main casing 10 and the inner wind-resistant casing 20 is adjusted, and the slant part 13 of the main casing 10 and the slant guide part 23 of the inner wind-resistant casing 20 are disposed to pass through a corresponding slant to adjust an interval between the slant part 13 and the slant guide part
 23. 10. The wind-resistant heating device of claim 9, wherein: a plurality of fixing parts 18 spaced apart at specific intervals is disposed alongside an inner circumference surface of the main casing 10 and coupled to an outer circumference surface of the inner wind-resistant casing 20, and the fixing parts 18 are coupled to the inner wind-resistant casing 20 so that a relative height of the fixing parts is adjustable.
 11. The wind-resistant heating device of claim 10, wherein: the fixing part 18 of the main casing 10 comprises an elastic body, and the fixing part is pressurized and coupled to the outer circumference surface of the inner wind-resistant casing 20 by applying an elastic force to the outer circumference surface.
 12. The wind-resistant heating device of claim 1, wherein: the inner wind-resistant casing 20 is spaced apart from the main casing 10 at a specific interval, and the inner wind-resistant casing 20 is protruded upward so that combusted air is discharged to the outside through the upper opening
 12. 13. The wind-resistant heating device of claim 1, wherein a plurality of fixing elastic parts 25 is radially disposed at a bottom of the inner wind-resistant casing 20 to pressurize and fix the non-electric heating body NB.
 14. The wind-resistant heating device of claim 13, wherein the fixing elastic parts 25 have elastic jaws 25 a formed therein and are engaged with a bottom of the non-electric heating body NB or a trapping jaw G formed in the outer circumference surface of the non-electric heating body NB.
 15. The wind-resistant heating device of claim 1, wherein: the outer wind-resistant casing 30 is provided to surround an outside of the main casing 10, and a plurality of guidance holes 31 is formed so that air is supplied to the air supply holes
 11. 16. The wind-resistant heating device of claim 15, wherein a bottom of the outer wind-resistant casing 30 is positioned to be seated in the slant part 13 of the main casing
 10. 17. The wind-resistant heating device of claim 16, wherein end guidance holes 31 a are formed at the bottom of the outer wind-resistant casing 30, so air introduced into the end guidance holes 31 a is naturally changed into a flow of air by the slant part
 13. 